JP2001326978A - Access controlling method and base station device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an efficient channel access controlling method on the basis of propagation delay time in random access. SOLUTION: In the access controlling method in a CDMA system having a base station using the random access, and a plurality of sender receiver terminals, when receiving a preamble signal from a sender receiver terminal to transmit a communication permission signal or a communication rejection signal to the sender receiver terminal, the base station stores the propagation delay time of the preamble signal in a storage device at the time of transmitting the communication rejection signal. Besides, in the access controlling method, when the base station receives the preamble signal from a plurality of sender receiver terminals and the propagation delay time of the storage device coincides nearly with the propagation delay time of the received preamble signal, the base station transmits the communication permission signal preferentially to the sender receiver terminal with the coincident propagation delay time.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a channel control method and circuit for random access using a preamble signal in a CDMA environment, and more particularly to a method for efficiently allocating access channels in a mobile communication system.

[0002]

2. Description of the Related Art Conventionally, in mobile communication, a control channel dedicated to control is provided separately from a communication channel, and when a call is generated, a base station controls a mobile station via this control channel to control communication. Communication is performed by allocating one of the channels. When the service area is large, a plurality of base stations are arranged in the service area. The range that radio waves can reach from each base station is called a zone.For communication channels, the same frequency is repeatedly used in a zone that is separated by a distance where interference noise does not interfere with communication, and measures have been taken to increase frequency use efficiency. You.

[0003] As for the control channel, the frequency utilization efficiency can be improved by using the same frequency in a zone separated by a distance where the interference noise does not hinder the control signal transmission.

In order to improve the frequency use efficiency, as a conventional example 1, Japanese Patent Laid-Open Publication No. Hei 3-6932 has a configuration in which a control signal transmitted from a mobile station designates a destination base station at the head thereof. The base station sends an empty signal indicating that a control signal can be sent from the mobile station and destination base station identification information when the mobile station in the own zone sends a control signal,
It is described that the base station stops transmitting an empty signal when the destination base station identification information of the control signal from the mobile station and the information transmitted by the base station match, and interference using the same frequency is described. It is possible to know at an early stage whether it is a signal from a mobile station in the zone or a signal from a mobile station in the own zone, and it controls the transmission of an empty signal, enabling efficient control. The benefits are described.

Japanese Patent Laying-Open No. 8-167885 has a detecting means for detecting the presence or absence of a carrier on a wireless network and a transmitting means for sending a carrier pulse signal to the wireless network in a pseudo manner. A confirmation unit for confirming a channel number used for transmission and reception of a data packet by a channel, and a control unit for performing contention control when contention for use of a wireless network occurs by a plurality of terminals, or It is described that a discriminating means for discriminating the data type of the data and a setting means for setting two levels of priorities for each data type discriminated using this discriminating means are described.

Japanese Patent Laid-Open Publication No. Hei 10-178386 discloses a CDMA system that performs random access. FIG. 6 shows a system configuration diagram. , The packet composed of the preamble part and the data part generated by the downlink signal generation part 45 is spread-modulated by the transmission processing part 44 and transmitted from the antenna 41 via the duplexer 42. In this case, the downlink reference signal can be transmitted at a time interval that matches the length of the preamble portion.

The mobile terminal 30 receives the downlink reference signal via the antenna 31 and the duplexer 32 by the receiving unit 33, detects the downlink reference signal in the transmission timing extracting unit 35, and converts it into a transmission timing signal. , Transmission unit 3
4 performs random access according to the transmission timing signal.

[0008] Delay profile measuring section 47 of base station 40
Calculates the correlation value of the preamble part of the random access signal from the mobile terminal 30 with the spreading code, obtains the delay profile based on the cyclic addition value obtained by reducing the influence of noise by the cyclic addition, and performs despreading processing 48 ₁ Add timing signals to ~ ₃ respectively. Despreaders 48 _1-3 despreads demodulating the received signal by the spreading code synchronized with the timing signal.

[0009] Thus, in the publication, when a packet consisting of a preamble part and a data part is spread-modulated by a short-period spreading code, a short-period spreading code is used at least in the preamble part or including the data part. , A delay profile is obtained based on the correlation value, and a timing signal according to the delay profile is extracted, thereby enabling reception processing by the RAKE method, improving reception characteristics, and improving the slotted Aloha method. Is applied, since the transmission and reception delay time can be estimated, even if spread modulation is performed with a long-period spreading code, synchronization can be achieved on the receiving side, and as a result, transmission power can be reduced, and a longer delay than a short period can be achieved. It is described that the profiles can be separated and random access is possible.

Japanese Patent Laid-Open Publication No. 2000-59850 describes a method of fairly and efficiently allocating an additional band in a cellular communication system that supports transmission and reception of data bursts with a mobile unit.

[0011] Further, to explain a conventional example, there is a mobile communication system using CDMA which uses random access as one of uplink channels from a mobile station to a base station. . This link channel is here called RACH (Random Access Channel)
Shall be called.

The RACH is composed of a message part 30 and a preamble signal 28 as shown in FIG.
Is used as a request signal to acquire a message part from the mobile station. In other words, message part 30
Since is shared by all mobile stations, the preamble signal 28 is used by the mobile station to request the base station for the right to use this message part.

Here, how to assign a finite message part to a plurality of mobile stations that have simultaneously requested using the preamble signal 28 is a problem in the base station. In this random access method, a mobile station is inevitably rejected for acquiring a message part, but once the rejected mobile station transmits a preamble signal again next time and requests for a message part, the mobile station is rejected. In other words, it is desirable that control to assign a message part preferentially be performed on the mobile station side. This is because, if such control is not performed, a mobile station often waits to acquire a message part for a long time.

As one method for performing the above operation on the base station side, information on the mobile station which once refused to acquire the message part is stored in the base station, and the next preamble signal is transmitted. If some of the mobile station information coincides with this, the message part is preferentially assigned to the mobile station having that information. However, here, what kind of mobile station information is stored and stored in the base station becomes a problem. As the simplest method, since the preamble signal is composed of a code string having a certain length, the configuration of this code string is changed for each mobile station and this is stored. However, this method cannot be applied to all mobile communication systems using CDMA. For example, even in a mobile communication system called W-CDMA which is scheduled to be introduced in various countries around the world after 2001, this RACH exists, but a code string constituting a preamble signal is transmitted to all mobile stations in the same area. There are only a dozen or so in common. Further, each time a mobile station transmits a preamble signal, one is randomly selected from a dozen or so types of code strings, so that the base station cannot analyze this code string and identify the transmitting mobile station. . Therefore, information for specifying another mobile station is required.

[0015]

Therefore, what has been noticed in the present invention is the propagation delay time of the preamble signal. C
In a system using DMA, the propagation delay time can be obtained almost exactly, and since this time depends on the position and environment where the mobile station is currently located, it is necessary to specify and identify the mobile station. Can be used.

In the present invention, in random access,
An object is to provide an efficient channel access control method based on a propagation delay time.

[0017]

SUMMARY OF THE INVENTION The present invention solves the above-mentioned problems. In an access control method in a CDMA system having a base station using random access and a plurality of transmitting / receiving terminals, the base station comprises: When receiving a preamble signal from a transmitting / receiving terminal and transmitting a communication permission signal or a communication rejection signal to the transmitting / receiving terminal, when transmitting the communication rejection signal, storing a propagation delay time of the preamble signal in a storage device. It is characterized by.

In the above access control method, when the base station receives the preamble signal from a plurality of transmitting / receiving terminals, the base station substantially matches the propagation delay time of the received preamble signal with the storage device. In this case, the communication permission signal is preferentially transmitted to the matching transmitting / receiving terminal.

The present invention also relates to a base station apparatus in a CDMA system having a base station apparatus using random access and a plurality of transmitting / receiving terminals, wherein the base station apparatus receives a preamble signal and a communication permission signal from the plurality of transmitting / receiving terminals. A receiving unit that receives transmission data of the transmitting / receiving terminal, a correlator unit that receives a baseband signal from the receiving unit and correlates with a plurality of predetermined reference preamble signals, and a signal from the correlator unit. A predetermined number of correlation values and a delay time at which the correlation value is detected are input, the reception of the preamble signal is determined, and a communication permission signal is returned or transmitted for the preamble signal determined to be received. A preamble signal determiner for determining whether to return a rejection signal,
A code generator for generating a communication permission signal or a communication rejection signal in accordance with the determination from the preamble signal determiner and outputting the generated signal to the transmission unit.

The present invention is conceptually based on Code Division Multiple Access (CDM) used in mobile communications and the like.
A) The present invention provides efficient control when performing random access using a preamble signal in a system.

In the present invention, referring to FIG. 1, first, the transceiver 1 receives the preamble signal 5 indicating the message part acquisition request from the transmission / reception terminals 2 and 3 while receiving the preamble signal 5. The propagation delay time of the preamble signal 5 which has been rejected and transmitted the NACK signal 7 is stored. Then, with respect to the preamble signal 5 received with the same or close to the stored propagation delay time, it is assumed that the signal is from the transmitting / receiving terminal 2 for which the transmitting / receiving terminal 1 has previously denied access. It is determined that the message part is preferentially assigned to the transmitting / receiving terminal 2 that has transmitted the preamble signal 5,
Transmit the K signal.

Therefore, even if access is denied once, as long as there is a message part that can be assigned to the next message part acquisition request by the preamble signal, the message part is assigned preferentially. The maximum waiting time required.

[0023]

Embodiments of the present invention will be described in detail with reference to the drawings.

(1) Description of Configuration FIG. 1 shows a schematic system diagram of an embodiment of the present invention.
The embodiment shown in FIG. 1 is an example in which the present invention is applied to the CDMA mobile communication system.
And the transmitting / receiving terminal 4
A preamble signal including a sequence of a plurality of codes is transmitted.

The transceiver 1 operates as a base station, and mainly includes the internal configuration of the base station 40 shown in FIG. 6 and storage means for storing the delay time of the preamble signal from the new transmitting / receiving terminal. The transceiver 1 receives preamble signals from the plurality of transmission / reception terminals 2 to 4 and transmits an ACK (permission) signal or a NACK (rejection) signal for each preamble signal. Here, the ACK signal is a signal transmitted when the use of the message part is permitted in response to the preamble signal, and the NACK signal is a signal transmitted when the use is rejected.

In the present embodiment, some code strings of preamble signals transmitted by the transmitting / receiving terminal 2, the transmitting / receiving terminal 3, and the transmitting / receiving terminal 4 can be commonly used by all transmitting / receiving terminals. However, it is assumed that it has not been decided for each transmitting and receiving terminal unit,
Further, it is assumed that each time transmission is performed in each transmitting / receiving terminal, it is different. Therefore, the transmitter / receiver 1 cannot determine from which transmitting / receiving terminal the signal is transmitted only by decoding the code string constituting the received preamble signal.

FIG. 2 is a block diagram of a channel access control unit in the transceiver 1 of FIG. The input to the correlator unit 13 in FIG. 2 is a signal demodulated to a baseband signal by a demodulator, and a code generator 15
Is also a baseband signal before being modulated by the modulator. The correlator unit 13, which is also a despreader, includes a despreader for despreading a spread spectrum signal and a transmission estimator for estimating a transmission path of a received signal passing through a plurality of transmission paths.

In the correlator unit 13, a preamble signal selected from a plurality of preamble signals determined in advance to be used with the transmitting / receiving terminal and a received baseband signal are despread and obtained. The correlation is obtained, and a predetermined number of correlation values and the delay time at which the correlation value is detected are output to the preamble signal determiner 14. In some cases, 16 types of the preamble signal are determined to form a spread code pattern of a spread spectrum spread method. Therefore, it is rare that the same preamble signal arrives and is received in an overlapping manner, but it is highly necessary to solve the problem of the collision. The number of correlators 13 is equal to the number of mobile stations that the base station can cover in advance or the number of receivable mobile stations set on the base station side. Also, in the present embodiment, the delay time of the signal of the preamble can be determined in the correlator unit 13 so that the delay time is determined by the delay profile shown by the graph of the reception level with respect to the delay time. For example, in the correlator unit 13,
It is obtained from a deviation (shift amount) when correlating the received baseband signal with the code string pattern peculiar to the preamble signal.

The preamble signal determiner 14 determines the reception of the preamble signal, and determines whether to return an ACK signal or a NACK signal to the preamble signal determined to be received. Even if a plurality of correlator units 13 are used, only one preamble signal discriminator 14 may be used. The mobile station of the transmission source of each preamble signal output from each correlator unit 13 and the preamble signal The set delay time is stored as a pair when necessary.

Further, the code generator 15 generates an actual ACK signal or NACK signal in accordance with a command from the preamble signal determiner 14, and outputs these to a modulator arranged in the transmission section. In the delay time storage device 16, the preamble signal determiner 14 stores a propagation delay time of a preamble signal for which a NACK signal is determined to be returned, for a predetermined time. This delay time storage device 16 is provided with the SR
It may be an AM or DRAM, or a plurality of registers.

When the preamble signal is received in relation to FIG. 6 and FIG. 2, the despreading processing section 48 of FIG.
The transmission control signal of the ACK / NACK signal is directly transmitted from the delay profile measurement unit 47 to the downlink signal generation unit 45 without using _1-3 . That is, the correlator 13 and the preamble signal determiner 14 in FIG. 2 correspond to a part of the delay profile measuring unit 47. The delay time storage device 16 is a storage device attached to the delay profile measurement unit 47. Incidentally, the timing signal from the timing generator 46 in FIG. 6 is input to the correlator 13.

(2) Description of Operation Regarding the operation of this embodiment, the system configuration diagram of FIG.
This will be described together with the processing flowchart of FIG.

First, as shown in FIG. 1A, it is assumed that the transmitting / receiving terminal 2 and the transmitting / receiving terminal 3 simultaneously transmit a preamble signal indicating a request to acquire a message part to the transceiver 1 as a base station. . At this time, the transceiver 1
, The preamble signal 5, the preamble signal 6
Are received. However, in the transceiver 1, even if the preamble signal 5 is transmitted from the transmission / reception terminal 2 and the preamble signal 6 is transmitted from the transmission / reception terminal 3, it cannot be determined from the code string constituting the preamble signal. The transceiver 1 that has received the preamble signal checks in the preamble signal determination 21 whether a message part can be assigned to the transmitting and receiving terminal that has transmitted each preamble signal. Here, if there is only one message part that can be assigned, the message part can be assigned only to one of the preamble signals, that is, the transmitting / receiving terminal.

In the case of the present embodiment, the transmitting / receiving terminal that transmitted the preamble signal 6, that is, the transmitting / receiving terminal 3,
A message part is assigned and a preamble signal 5
Is not assigned to the transmitting / receiving terminal that has transmitted, that is, the transmitting / receiving terminal 2. Therefore, for preamble signal 6, ACK signal 8 indicating that use of the message part is permitted is transmitted,
The transmitting / receiving terminal 3 can access the message part (26). On the other hand, a NACK signal 7 indicating that access to the preamble signal 5 is not permitted is transmitted to the transceiver 1.
Sent from Further, at this time, in the transceiver 1, the NA
The propagation delay time of the preamble signal 5 that has transmitted the CK signal 7 is stored (22). The transmitting / receiving terminal 3 permitted to use the message part can transmit / receive data or transmit / receive digital data of voice or image for the message part of the message channel.

Thereafter, separately, as shown in FIG.
It is assumed that a preamble signal indicating a request for acquiring a message part has been transmitted again from the transmitting / receiving terminal 2 and the transmitting / receiving terminal 4 to the transceiver 1 at the same time. At this time, it is assumed that the transmitting / receiving terminal 2 transmits a preamble signal of a code string different from the previous one, and the transmitting / receiving terminal 1 receives two signals, a preamble signal 9 and a preamble signal 10. The transceiver 1 that has received the preamble signals 9 and 10 checks whether a message part can be assigned to the transmitting and receiving terminal that has transmitted each preamble signal, as in the above case. At this time, if there is only one message part that can be assigned again, the transceiver 1
The propagation delay time of the preamble signal 5 to which the NACK signal has been returned before is read (23), and the propagation delay time of the preamble signal 9 and the preamble signal 10 received this time is compared.

The preamble signal received this time with a propagation delay time equal to or close to the propagation delay time of the preamble signal 5 is assigned a message part with priority as the preamble signal determination (24). This is to prevent a transmitting / receiving terminal once refused to use the message part from being refused again, and if the time interval between the first and second transmissions of the transmitting / receiving terminal is sufficiently short. Since the change in the propagation delay time is extremely small, the transceiver 1 can recognize whether or not the transmitting / receiving terminal has previously refused to use the message part based on the propagation delay time. is there.

As a result, when it is determined that the propagation delay time of the preamble signal 9 is equal to or sufficiently close to the propagation delay time of the preamble signal 5, the transceiver 1
Regards the transmitting and receiving terminal that transmitted these two preamble signals as the same, and preferentially allocates a message part to the transmitting and receiving terminal. Therefore, an ACK signal is returned for the preamble signal 9 (11), and a NACK signal is returned for the preamble signal 10 (1).
2) As a result, the transmitting / receiving terminal 2 acquires the message channel to make it accessible (27), and
Means that the message part could not be obtained.

Finally, in the transceiver 1, the previously stored propagation delay time of the preamble signal 5 is deleted.
The propagation delay time of the preamble signal 10 for which access has been newly rejected this time is stored (25), and thereafter, the above processing is repeated.

The operation of the channel access control unit in the transceiver 1 shown in FIG. 2 will be described with reference to the flowchart of FIG. In FIG. 2, first, the demodulated received baseband signal is input to the correlator unit 13 (S1).
1). The correlator 13 calculates the time cross-correlation between the received baseband signal and the code string pattern unique to each preamble signal, and determines the correlation value where the correlation is high for each preamble signal and its delay time, based on the preamble signal determination. It is output to the device 14 (S12).

In the preamble signal determiner 14,
A threshold determination process based on a certain correlation value is performed first, and if the correlation value is below a certain level, it is excluded from reception preamble signal candidates. After that, in the remaining reception preamble signal, the priority of channel assignment based on the correlation value and the delay time is determined. At this time, the propagation delay time of the preamble signal, which is low in priority while proceeding to this priority determination stage a certain time before and is denied access because it is larger than the reception capacity, is stored in the delay time storage device 16. This value is compared with the delay time of the newly received preamble signal (S13).

If there is a received preamble signal that matches or is close to the held delay time, a high priority is given to the preamble signal, and a message part is assigned with priority. Finally, for the preamble signal to which the message part is assigned, AC
For the K signal, a NACK signal is generated by the code generator 15 for a preamble signal to which no channel is allocated and access is rejected (S16), and is output to the modulator (S17).

Next, it is determined whether or not a NACK signal has been transmitted (S18).
The propagation delay time of the preamble of the new terminal transmitting and receiving the K signal is stored in the delay time storage device 16 (S19).

As described above, in the preamble signal to which the NACK signal has been transmitted, the propagation delay time is stored in the delay time storage device 16 and is used for determining the priority in the later message part allocation.

In the above embodiment, the priority is determined using the propagation delay time as a parameter. However, the priority may be determined by adding the received power from the new transmitting / receiving terminal. That is, when the transceiver 1 is located at the same distance as a plurality of new transmission / reception terminals, all of the propagation delay times tend to coincide with each other and cannot be determined only by the propagation delay time. Since the terminal can easily receive the highly reliable transmission data, when the propagation delay time and the reception power match with priority, the ACK signal is transmitted to the new transmitting / receiving terminal that has transmitted the preamble signal. Further, not only the reception power but also Eb / N0 (signal 1
Energy per bit / noise power spectral density)
Or the data error rate of the preamble signal may be determined as a parameter. In these cases, if a NACK signal has been transmitted beforehand, the storage device 16 stores the propagation delay time and reception power, Eb / N0, data error rate, etc. of the preamble signals from a plurality of new transmitting / receiving terminals that have transmitted the NACK signal. Shall be stored in

The present invention is not limited to the above embodiment, and can be applied to, for example, an autonomous decentralized system without base station control and an indoor wireless system. Further, the present invention can be applied not only to CDMA but also to a system using spread spectrum communication technology and other systems capable of measuring a propagation delay time. Particularly, WLL (Wireless Local) such as wireless LAN
(Loop) and Bluetooth (Blu) that carry small area propagation with low power
It is suitable for a wireless system that dislikes wired wiring, such as etooth, because the propagation delay time is always constant. On the other hand, when the transmitting / receiving terminal is a mobile terminal, the propagation delay time may be different, which is not preferable. However, since the mobile terminal does not always move, there is no objection to the application.

Further, the base station of the transceiver may have a relay function in communication between the transmission / reception terminal and the transmission / reception terminal in cooperation with another base station. The present invention can also be applied to a system connected to a transmitting / receiving terminal and another telephone line.

[0047]

As described above, according to the present invention,
In a transceiver that controls random access, while receiving a preamble signal indicating a message part acquisition request of the transmitting and receiving terminal, even if the request is once rejected due to insufficient reception capacity, the message part acquisition request by the next preamble signal will be On the other hand, message parts are preferentially allocated as long as there is room. Therefore, the maximum waiting time required for the transmitting / receiving terminal to acquire the message part can be reduced. In other words, it can be said that the situation in which the transmitting and receiving terminal cannot wait for a long time can be eased.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram of a configuration of a CDMA system according to the present invention.

FIG. 2 is a partial configuration diagram of a base station device of the CDMA system according to the present invention.

FIG. 3 is a sequence diagram of a CDMA system according to the present invention.

FIG. 4 is a flowchart of a CDMA system according to the present invention.

FIG. 5 is a data configuration diagram of a conventional CDMA system using random access.

FIG. 6 is a configuration diagram of a conventional CDMA system using random access.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Transceiver (base station apparatus) 2, 3, 4 Transmission / reception terminal 5, 6 Preamble signal 7 NACK signal 8 ACK signal 13 Correlator part 14 Preamble signal judgment device 15 Code generator 16 Delay time storage device 30 Mobile terminal 40 Base station

Claims (7)

[Claims] 1. An access control method in a CDMA system having a base station using a random access scheme and a plurality of transmitting / receiving terminals, wherein the base station receives a preamble signal from the transmitting / receiving terminal and permits communication in response to the preamble signal. When transmitting a signal or a communication rejection signal to the transmission / reception terminal, if the communication rejection signal is transmitted, a propagation delay time of the preamble signal is stored in a storage device. 2. The access control method according to claim 1, wherein the base station can receive transmission data from the transmitting / receiving terminal in a message part when transmitting the communication permission signal. Access control method. 3. The access control method according to claim 1, wherein the base station receives the preamble signal from a plurality of the transmitting / receiving terminals, and receives the preamble signal from the plurality of transmitting / receiving terminals. An access control method, wherein when the transmission delay time substantially coincides with the transmission delay time, the communication permission signal is preferentially transmitted to the transmission / reception terminal that matches the transmission delay time. 4. The access control method according to claim 1, wherein the base station, when transmitting the communication rejection signal, propagates a propagation delay time of a preamble signal corresponding to the communication rejection signal, a received power or Eb / N0 (energy / noise power spectral density per signal bit) or data error rate is stored in the storage device 16, and the priority when the next preamble signal is received in duplicate is determined. Access control method. 5. A base station apparatus in a CDMA system having a base station apparatus using a random access method and a plurality of transmitting / receiving terminals, wherein said transmitting / receiving terminal receives a preamble signal and a communication permission signal from said plurality of transmitting / receiving terminals. A receiving unit that receives the transmission data, a correlator unit that receives a baseband signal from the receiving unit and correlates with a plurality of predetermined reference preamble signals, and a determined correlator unit from the correlator unit. The correlation value of the number and the delay time at which the correlation value is detected are input, the reception of the preamble signal is determined, and a communication permission signal is returned or the communication rejection signal is returned for the preamble signal determined to be received. A preamble signal determiner for determining whether to return, and generating a communication permission signal or a communication rejection signal in accordance with the determination from the preamble signal determiner. And a code generator for outputting to a transmission unit. 6. The base station apparatus according to claim 5, wherein
The base station apparatus further includes a delay time storage device that stores the delay time of the preamble signal when a communication rejection signal is returned from the preamble signal determiner. 7. The base station device according to claim 6, wherein
When the preamble signal is congested, the communication permission signal is transmitted to the transmitting / receiving terminal that has output one preamble signal, and the communication rejection signal is transmitted to the other transmitting / receiving terminal that has output the other preamble signal, and The delay time of the preamble signal of the transmitting and receiving terminal is stored in the delay time storage device, and the preamble signal determiner selects the one preamble signal when the delay time of the one preamble signal is the delay time storage device. A delay time substantially equal to the delay time stored in the base station.